Related papers: Manipulating spectral transitions and photonic transmission in a non-Hermitian optical system through nanoparticle perturbations

Manipulating spectral transitions and photonic transmission in a non-Hermitian optical system through nanoparticle perturbations

URL: http://arxiv.org/abs/2411.14862v1
Date: Fri, 22 Nov 2024 11:22:34 GMT
Title: Manipulating spectral transitions and photonic transmission in a non-Hermitian optical system through nanoparticle perturbations
Authors: Bo-Wang Zhang, Cheng Shang, J. Y. Sun, Zhuo-Cheng Gu, X. X. Yi,
Abstract summary: We study spectral transitions and photon transmission in a linear spinning resonator perturbed by nanoparticles. Our findings offer valuable insights for the design of dissipative quantum devices under realistic conditions.
Score: 0.3495246564946556
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Abstract: In recent years, extensive research has been dedicated to the study of parity-time ($\mathcal{PT}$) symmetry, which involves the engineered balance of gain and loss in non-Hermitian optics. Complementary to $\mathcal{PT}$ symmetry, the concept of anti-$\mathcal{PT}$ symmetry has emerged as a natural framework for describing the dynamics of open systems with dissipations. In this letter, we study spectral transitions and photon transmission in a linear spinning resonator perturbed by nanoparticles. First, we demonstrate that by precisely manipulating the nanoparticle perturbations, the eigenvalues(or spectra) of a non-Hermitian system satisfying anti-$\mathcal{PT}$ symmetry can transit to that of a quasi-closed Hermitian system. Second, we outline the essential conditions for constructing a quasi-closed system and analyze its dynamic behavior with respect to photon transmission. By adjusting the rotational angular velocity of the spinning resonator and the strength of the nanoparticle perturbations, the quasi-closed system enables a variety of photon distribution behaviors, which may have significant applications in quantum devices. Our findings offer valuable insights for the design of dissipative quantum devices under realistic conditions and for understanding their responses to external perturbations.

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